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Literature DB >> 14367775

Accumulation of sulfate labelled with S35 by rat tissue in vitro.

Abstract

Rat kidney slices incubated in vitro may show, in parallel with other shifts in electrolyte content, a striking capacity for accumulating sulfate ion (sulfate labelled with S(35)). The uptake is reversed or reduced by CN(-), cooling to room temperature, and by interference with adequate oxygenation. Under the conditions of the experiment, the presence in the medium of sodium acetate and glucose as substrates was found to be without measurable effect on the accumulation. The extent of sulfate uptake is related to the ionic composition of the medium in which the tissue is incubated, for the uptake occurs optimally only in the presence of a K(+) level of about 0.04 M, and is decreased as the concentration of Na(+) rises. Likewise, when Ca(++), Mg(++), or choline is present in the medium, sulfate accumulation may be depressed. In addition to renal cortex, kidney medulla and liver showed capacity for sulfate accumulation, whereas no convincing evidence for significant uptake was obtained with strips of aorta, colon, or diaphragm.

Entities: Chemical Disease Species

Keywords: SULFATES/metabolism

Mesh：

Substances：
Sulfates
Sodium

Year: 1955 PMID： 14367775 PMCID： PMC2147499 DOI： 10.1085/jgp.38.5.599

Source DB: PubMed Journal: J Gen Physiol ISSN： 0022-1295 Impact factor: 4.086

16 in total

7. Contraluminal sulfate transport in the proximal tubule of the rat kidney. I. Kinetics, effects of K+, Na+, Ca2+, H+, and anions.

Authors: K J Ullrich; G Rumrich; S Klöss
Journal: Pflugers Arch Date: 1984-11 Impact factor: 3.657

Accumulation of sulfate labelled with S35 by rat tissue in vitro.

1. Transport of phenol red in the flounder renal tubule.

2. Autoradiographic observations on the incorporation of S35-labeled sodium sulfate in the rabbit fetus.

3. An evaluation of radiosulfate for the determination of the volume of extracellular fluid in man and dogs.

4. OBSERVATIONS ON THE FATE OF SODIUM SULFATE INJECTED INTRAVENOUSLY IN MAN.

5. THE URINARY EXCRETION OF INGESTED RADIOACTIVE SULFUR.

6. The distribution and excretion of S35 sodium sulfate in the albino rat.

7. Studies on potassium accumulation by rabbit kidney slices; effect of metabolic activity.

8. Use of isolated renal tubules for the examination of metabolic processes associated with active cellular transport.

9. In vitro incorporation of C14 glycine and S35 sulfate into protein by human colon mucosa.

10. A study of the fluid uptake of rat kidney slices in vitro.

1. Cell electrical potentials during enhanced sodium extrusion in guinea-pig kidney cortex slices.

2. Mercaptomerin and water exchange in cortex slices of rat kidney.

3. Biosynthesis of intestinal mucins. 1. Survey of incorporation of [35S] sulphate by isolated gastrointestinal tissues.

4. Sulphate-ion/sodium-ion co-transport by brush-border membrane vesicles isolated from rat kidney cortex.

5. Energy barriers to sodium extrusion from sodium-rich kidney cortex slices.

6. Extracellular fluid in individual tissues and in whole animals: the distribution of radiosulfate and radiobromide.

7. Contraluminal sulfate transport in the proximal tubule of the rat kidney. I. Kinetics, effects of K+, Na+, Ca2+, H+, and anions.

8. Use of the tissue slice technique for evaluation of renal transport processes.

9. Accumulation of sulfate by mitochondria of rat kidney cortex.

10. Further observations on uptake of S35-labelled sulfate by renal tissue in vitro.